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Venus Climate Mission Study:
Orbiter – GSFC Balloon – JPL Instruments – GSFC Sondes ‐ GSFC and JPL Aeroshell – Ames Mission architecture – GSFC and JPL
David Grinspoon, VCM Science Champion Alexander Pavlov, GSFC Science RepresentaFve NASA/GSFC Michael Adams, Study Lead Michael Amato, New Business Manager Nerses Armani, Mechanical Charles Baker, Systems Heather Bradshaw, Thermal Kara Chaprnka, CosFng John Galloway, Instruments Lori Glaze, Science William Horne, CommunicaFons Carol Ladd, Report ProducFon William Lawson, CosFng David Mangus, ACS Greg Marr, Flight Dynamics Robin Mauk, Systems Richard Mills, Electrical Systems Tom Spitzer, Power ScoR Starin, ACS Barbara TalboR, Report Graphics Steven Tompkins, Mission OperaFons and Ground System Sanjay Verma, CosFng Carl Wales, Systems Graham Webster, Propulsion
JPL Tibor Balint, Study Lead Harry Balian, SoTware DeberaF ChaRopadhyay, Risk Loucas Christodoulou, Propulsion/InflaFon Douglas Equils, Ground Systems Dwight Geer, CDS Jeff Hall, Balloon Design and Sizing Support Casey Heeg, Systems Jennifer Herman, Power ScoR Howe, ConfiguraFon Viktor Kerzhanovich, Balloon Design and Sizing Support Ryan Lim, ACS Michael Mercury, Deputy Systems Robert Miyake, Thermal Jeffrey Parker, Mission Design Jamie PiacenFne, ConfiguraFon Michael Pugh, Telecom Leigh Rosenberg, CosFng Brian Schratz, Telecom Partha ShakkoRai, Thermal Evgeniy Sklyanskiy , EDI/Probe Descent William Smythe, Science OperaFons MaRhew Spaulding, Mechanical Paul Stella, Power Marc Walch, Instruments Keith Warfield, Facilitator
NASA/ARC Ethiraj Venkatapathy, Aeroshell Chief Technologist Gary Allen, Systems Analyst Ken Hamm, Structural Analyst Todd White, Aeroshell Engineer
Venus Climate Mission Science Objectives • Characterize the strong CO2 greenhouse atmosphere of Venus,
including variability.
Venus Climate Mission Science Objectives
• Characterize the nature and variability of Venus‘ superrotating atmosphere.
South polar vortex
VEX
PV
Probes: Winds decrease with altitude
VEX East-west winds, decreasing at the poles
Venus Climate Mission Science Objectives
• Characterize surface/atmosphere chemical exchange in the lower atmosphere.
Venus Climate Mission Science Objectives • Search for atmospheric evidence of climate change on Venus
• Determine the origin of Venus’ atmosphere and the sources and sinks driving evolution of the atmosphere.
• Understand implications of Venus’ climate evolution for the long-term fate of Earth.
Venus Climate Mission Science Objectives
Payload Balloon: • Tracking of balloon motions to measure winds,
thermal tides and super-rotation. • Atmospheric Structure Instrument will measure P
and T over local time and latitude. • Accelerometer will measure vertical winds and
turbulence. • Nephelometer to measure cloud particle size and
composition. • Net Flux Radiometer will measure upwelling and
downwelling solar and IR flux. • Tunable Laser Spectrometer will measure cloud
and atmospheric composition. • Neutral Mass Spectrometer will measure
composition including noble gases and isotopes.
Payload Drop Sondes (2): • Atmospheric Structure Instrument will measure
P, T, winds and stability on descent at 3 locations with differing local solar times.
• Net Flux Radiometer will measure radiation balance and composition over 3 vertical traces from the cloud base to the surface.
Mini-Probe: Above plus: • Neutral Mass Spectrometer will measure
vertical profiles of key trace gases in the lower atmosphere.
Carrier Spacecraft: • VIS-IR camera to provide hemispheric context for in
situ science, measure cloud motions, and characterize winds.
Science Instrument and Data Summary Gondola Mini Probe Drop Sonde (each) Orbiter
Neutral Mass Spectrometer (NMS)
NMS NFR
IR Imager
Tunable Laser Spectrometer (TLS)
NFR ASI
Nephelometer ASI
Net Flux Radiometer (NFR)
Atmospheric Structure Instrument (ASI)
(Doppler ranging through telecom system)
Total science data return from in situ ~135 Mbits
Balloon: 128 Mbits Mini probe: 5 Mbits
Drop sondes: 1 Mbits each
Venus Climate Mission Science Traceability Matrix
Science Objective Measurement Instrument Functional Requirement Characterize the strong CO2 greenhouse atmosphere of Venus, including variability.
Upward and Downward visible and IR fluxes, atmospheric composition, aerosol composition and size distribution.
ASI, Nephelometer, Radiometer, TLS, NMS
Three decent traces at varied longitude and solar zenith angles. Four complete gondola/balloon system circumnavigations of Venus.
Characterize the dynamics and variability of Venus’ superrotating atmosphere
Cloud motions, global and local wind speeds at multiple altitudes, P, T, stability, radiation balance, thermal tides & turbulence.
VIS-IR Camera, Gondola/Balloon system tracking, ASI, Descent Spectrometer, Accelerometer, Radiometer.
Three descent traces at vaied longitude and solar zenith angles. Four complete gondola/balloon system circumnavigations of Venus
Constrain surface/atmosphere chemical exchange in the lower atmosphere.
Measure stable isotopes and trace reactive gases and with altitude.
NMS, TLS One descent trace.
Search for atmospheric evidence of climate change on Venus.
Stable isotopes and atmospheric composition.
NMS, TLS In situ sampling of atmospheric gases and aerosols, descent trace.
Determine the origin of Venus’ atmosphere and the sources and sinks driving evolution of the atmosphere.
Noble gases and isotopes. Stable isotopes.
NMS, TLS In situ sampling.
Understand implications of Venus’ climate evolution for the long-term fate of Earth.
Stable isotopes (D/H,S,O,N) rare gases and isotopes,
NMS, TLS In situ sampling of atmosphere and cloud aerosols.
For this study, the Mini‐ Probe and Drop Sondes have not been opFmized for mass or volume. Further design efforts will reduce the size and mass of these units, resulFng in a more efficient Gondola/Balloon System design.
Mission Design: Concept of Operations • Launch:
– November 2, 2021 – On an Atlas V-551 Launch Vehicle
• Entry System (Aeroshell) release from Carrier: – March 29, 2022 – 10 days before VOI & Probe entry
• Venus Orbit Insertion (VOI) & Entry System entry – April 7, 2022 – VOI & Entry System entry is separated by ~2 hours – Entry is seen by the orbiter – Entry phase + initial data taking includes telecom to orbiter
• In situ Mission Phase for the balloon / probe / sondes: – April 7, 2022 to April 28, 2022 – 21 days baseline balloon operations – Probe is released after atmospheric entry (45 min descent) – Two drop sondes are released sometime during the 3 weeks in
situ operations (45 min descent)
Mission Design: Venus Orbit Insertion
White: Aeroshell trajectory aTer release from spacecraT Blue : SpacecraT trajectory prior to VOI Yellow: SpacecraT trajectory aTer VOI View from sun, Earth behind Venus
The orbiter will see the balloon from entry through the first 2 hours
Mission Design: Orbit & Balloon Path View of Orbit and Entry
Vehicle at Fme of entry as viewed from Earth.
The balloon’s iniFal locaFon and path southward.
Note: preliminary
24 hour orbit; apoapse at 66,000 km
Mission Design: Balloon Path Over 21 Days
Earth
Sun Balloon in darkness
EDI Point
The path of the balloon in Venus’ atmosphere, assuming: - Constant Zonal wind velocity of 60 m/s. - Constant Meridional wind velocity of 4 m/s (poleward motion). - Motion ceases at +/- 85° latitude.
South Pole View
Depending on the wind conditions, the balloon will circumnavigate Venus about 5 times
Copyright © National Academy of Sciences. All rights reserved.
Vision and Voyages for Planetary Science in the Decade 2013-2022
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Conclusions The Venus Climate Mission will produce fundamental new advances by creaFng a detailed portrait of climate and global change on Venus. This will contribute greatly to understanding of terrestrial planet system science and the mechanisms of climate stability and climate change on Earth‐like planets. This will also help to evaluate, validate and contextualize terrestrial climate models and their applicaFons. These important applicaFons include understanding the divergent history of Venus, Earth and Mars, evaluaFng the habitability of extrasolar terrestrial planets, assessing the likely magnitude of anthropogenic climate change under various projected forcings, and learning the long term fate of the Earth.
Conclusions
The current VCM concept is not opFmized for mass / volume / power; this will allow future proposers to design a broader science concept for similar or lower costs. InternaFonal contribuFons could ease cost pressure and/or provide addiFonal mission elements to broaden this flagship mission into a wider science science invesFgaFon including surface mapping and in situ surface science.